BACKGROUND: High-quality attenuation maps are critical for attenuation correction of myocardial perfusion single photon emission computed tomography studies. The filtered backprojection (FBP) approach can introduce errors, especially with low-count transmission data. We present a new method for attenuation map reconstruction and examine its performance in phantom and patient data. METHODS AND RESULTS: The Bayesian iterative transmission gradient algorithm incorporates a spatially varying gamma prior function that preferentially weights estimated attenuation coefficients toward the soft-tissue value while allowing data-driven solutions for lung and bone regions. The performance with attenuation-corrected technetium 99m sestamibi clinical images was evaluated in phantom studies and in 50 low-likelihood patients grouped by body mass index (BMI). The algorithm converged in 15 iterations in the phantom studies. For the clinical studies, soft-tissue estimates had significantly greater uniformity of mediastinal coefficients (mean SD, 0.005 cm(-1) vs 0.011 cm(-1); P < .0001). The accuracy and uniformity of the Bayesian iterative transmission gradient algorithm were independent of BMI, whereas both declined at higher BMI values with FBP. Attenuation-corrected perfusion images showed improvement in myocardial wall variability (4.8% to 4.1%, P = .02) for all BMI groups with the new method compared with FBP. CONCLUSION: This new method for attenuation map reconstruction provides rapidly converging and accurate attenuation maps over a wide spectrum of patient BMI values and significantly improves attenuation-corrected perfusion images.
BACKGROUND: High-quality attenuation maps are critical for attenuation correction of myocardial perfusion single photon emission computed tomography studies. The filtered backprojection (FBP) approach can introduce errors, especially with low-count transmission data. We present a new method for attenuation map reconstruction and examine its performance in phantom and patient data. METHODS AND RESULTS: The Bayesian iterative transmission gradient algorithm incorporates a spatially varying gamma prior function that preferentially weights estimated attenuation coefficients toward the soft-tissue value while allowing data-driven solutions for lung and bone regions. The performance with attenuation-corrected technetium 99m sestamibi clinical images was evaluated in phantom studies and in 50 low-likelihood patients grouped by body mass index (BMI). The algorithm converged in 15 iterations in the phantom studies. For the clinical studies, soft-tissue estimates had significantly greater uniformity of mediastinal coefficients (mean SD, 0.005 cm(-1) vs 0.011 cm(-1); P < .0001). The accuracy and uniformity of the Bayesian iterative transmission gradient algorithm were independent of BMI, whereas both declined at higher BMI values with FBP. Attenuation-corrected perfusion images showed improvement in myocardial wall variability (4.8% to 4.1%, P = .02) for all BMI groups with the new method compared with FBP. CONCLUSION: This new method for attenuation map reconstruction provides rapidly converging and accurate attenuation maps over a wide spectrum of patient BMI values and significantly improves attenuation-corrected perfusion images.
Authors: Mathew Shotwell; Balkrishna M Singh; Charlotte Fortman; Brian D Bauman; Jennifer Lukes; Myron C Gerson Journal: J Nucl Cardiol Date: 2002 Jan-Feb Impact factor: 5.952
Authors: Gavin L Noble; Alan W Ahlberg; Aravind Rao Kokkirala; S James Cullom; Timothy M Bateman; Giselle M Cyr; Deborah M Katten; Glenn D Tadeo; James A Case; David M O'Sullivan; Gary V Heller Journal: J Nucl Cardiol Date: 2009-01-22 Impact factor: 5.952
Authors: Harshal R Patil; Timothy M Bateman; A Iain McGhie; Eric V Burgett; Staci A Courter; James A Case; Gary V Heller Journal: J Nucl Cardiol Date: 2013-11-21 Impact factor: 5.952
Authors: Afrooz Ardestani; Alan W Ahlberg; Deborah M Katten; Krista Santilli; Donna M Polk; Timothy M Bateman; Gary V Heller Journal: J Nucl Cardiol Date: 2013-11-21 Impact factor: 5.952
Authors: Ryan A Rava; Kenneth V Snyder; Maxim Mokin; Muhammad Waqas; Ariana B Allman; Jillian L Senko; Alexander R Podgorsak; Mohammad Mahdi Shiraz Bhurwani; Jason M Davies; Elad I Levy; Adnan H Siddiqui; Ciprian N Ionita Journal: Neuroradiol J Date: 2020-06-23
Authors: Carmelo V Venero; Gary V Heller; Timothy M Bateman; A Iain McGhie; Alan W Ahlberg; Deborah Katten; Staci A Courter; Robert J Golub; James A Case; S James Cullom Journal: J Nucl Cardiol Date: 2009-07-07 Impact factor: 5.952
Authors: Timothy M Bateman; Gary V Heller; A Iain McGhie; Staci A Courter; Robert A Golub; James A Case; S James Cullom Journal: J Nucl Cardiol Date: 2009-06-23 Impact factor: 5.952